Abstract: Indoor mapping and modular control for UAVs and other autonomous vehicles, and associated systems and methods. A representative unmanned aerial vehicle system includes a body, a propulsion system carried by the body, a sensor system carried by the body, and a controller carried at least in part by the body and operatively coupled to the propulsion system and the sensor system. The controller is programmed with instructions that, when executed, operate in a first autonomous mode and a second autonomous mode. In the first autonomous mode, the instructions autonomously direct the propulsion system to convey the body along a first route within an indoor environment. While the body travels along the first route, the instructions receive inputs from the sensor system corresponding to features of the indoor environment. The features are stored as part of a 3-D map.

Abstract: Indoor mapping and modular control for UAVs and other autonomous vehicles, and associated systems and methods. A representative unmanned aerial vehicle system includes a body, a propulsion system carried by the body, a sensor system carried by the body, and a controller carried at least in part by the body and operatively coupled to the propulsion system and the sensor system. The controller is programmed with instructions that, when executed, operate in a first autonomous mode and a second autonomous mode. In the first autonomous mode, the instructions autonomously direct the propulsion system to convey the body along a first route within an indoor environment. While the body travels along the first route, the instructions receive inputs from the sensor system corresponding to features of the indoor environment. The features are stored as part of a 3-D map.

Abstract: Certain examples described herein relate to modelling a three-dimensional space. Image data from at least one capture device is used to generate a three-dimensional model of the three-dimensional space. In certain examples, the three-dimensional model is segmented into active and inactive portions based on at least one model property. The examples are configured to use the active portions to update the three-dimensional model over time. Registration is also performed to align active portions of the three-dimensional model with inactive portions of the three-dimensional model over time. The registration aligns active portions of the three-dimensional model generated following an observation of a region of the three-dimensional space with inactive portions of the model generated following at least one previous observation of said region.

Abstract: Indoor mapping and modular control for UAVs and other autonomous vehicles, and associated systems and methods. A representative unmanned aerial vehicle system includes a body, a propulsion system carried by the body, a sensor system carried by the body, and a controller carried at least in part by the body and operatively coupled to the propulsion system and the sensor system. The controller is programmed with instructions that, when executed, operate in a first autonomous mode and a second autonomous mode. In the first autonomous mode, the instructions autonomously direct the propulsion system to convey the body along a first route within an indoor environment. While the body travels along the first route, the instructions receive inputs from the sensor system corresponding to features of the indoor environment. The features are stored as part of a 3-D map.

Abstract: Automated battery servicing, including charging and/or replacement, for unmanned aerial vehicles, and associated systems and methods. A representative system includes a landing structure, at least one positioning element located proximate to the landing structure and movable relative to the landing structure to re-position an unmanned aerial vehicle at the landing structure, and a battery service device positioned proximate to the landing structure. The battery service device is configured to (a) charge a battery carried by the unmanned aerial vehicle at the landing structure, or (b) remove and replace the battery carried by the unmanned aerial vehicle at the landing structure, or (c) both (a) and (b).

Abstract: Certain examples described herein relate to modelling a three-dimensional space. Image data from at least one capture device is used to generate a three-dimensional model of the three-dimensional space. In certain examples, the three-dimensional model is segmented into active and inactive portions based on at least one model property. The examples are configured to use the active portions to update the three-dimensional model over time. Registration is also performed to align active portions of the three-dimensional model with inactive portions of the three-dimensional model over time. The registration aligns active portions of the three-dimensional model generated following an observation of a region of the three-dimensional space with inactive portions of the model generated following at least one previous observation of said region.